Finite and Infinite W Algebras and their Applications

Abstract

In this paper we present a systematic study of W algebras from the Hamiltonian reduction point of view. The Drinfeld-Sokolov (DS) reduction scheme is generalized to arbitrary sl2 embeddings thus showing that a large class of W algebras can be viewed as reductions of affine Lie algebras. The hierarchies of integrable evolution equations associated to these classical W algebras are constructed as well as the generalized Toda field theories which have them as Noether symmetry algebras. The problem of quantising the DS reductions is solved for arbitrary sl2 embeddings and it is shown that any W algebra can be embedded into an affine Lie algebra. This also provides us with an algorithmic method to write down free field realizations for arbitrary W algebras. Just like affine Lie algebras W algebras have finite underlying structures called `finite W algebras'. We study the classical and quantum theory of these algebras, which play an important role in the theory of ordinary W algebras, in detail as well as some aspects of their representation theory. The symplectic leaves (or W-coadjoint orbits) associated to arbitrary finite W algebras are determined as well as their realization in terms of bosoic oscillators. Apart from these technical aspects we also review the potential applications of W symmetry to string theory, 2-dimensional critical phenomena, the quantum Hall effect and solitary wave phenomena. This work is based on the Ph.D. thesis of the author.

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